DE2647354C2 - Method and device for the synchronization of TDMA communication networks - Google Patents

Description

25th

The invention relates to a method and a device for maintaining synchronization a number of time division multiplexed with multiple access via a communication link (TDMA system) Interconnected stations in the event of failure of a synchronization pulse, which is normally within a certain predetermined cycle duration occurs and in the following as a primary sync pulse is designated

In recent years a number of satellite communication systems have been proposed and some have also been built; at least some of them are still in use. In a certain type of this satellite communication system, which has proven to be particularly economical, a time-division multiplex transmission method with multiple access is used, which in the following is referred to as the TDMA system (Time Division Multiple Access System) in accordance with the international abbreviation used in this communication system A plurality of earth stations transmit the information in pulse form (for example as so-called data bursts) to the satellite as a relay station, which in turn transmits this information to the other earth stations that each earth station is assigned a prescribed time period (a specific time slot) for transmission and reception, so that the individual transmissions arrive at the satellite in chronological order. As long as the respective broadcasts are received, a communication link is guaranteed to the extent that the satellite forwards the information it has collected to one or more other earth stations. Correct synchronization is an essential prerequisite for the proper functioning of TDMA systems. A loss of or incorrect synchronization generally leads to a transmission disruption due to the temporal overlap of the individual transmission channels at the satellite. It is obvious to a person skilled in the art that in such cases the result is a complete mess of the overlapping transmission paths, so that the satellite is no longer able to pass on the information sent to it.

In order to synchronize TDMA systems of this type, a reference station is generally determined In addition to each piece of information to be transmitted, a synchronization signal or, in short, a "synchronization pulse" also transmits This sync pulse is received by the satellite and to all other stations sent out again in the same way as the information collected by the satellite. The reception of the Synchronizing pulse at any one of the earth stations enables the station by means of the synchronizing pulse set the correct synchronization for the transmission in question. A typical example of synchronization systems this type is described in US Pat. No. 3,562,432. In this patent it is stated that Perfect synchronization is of such importance that if the sync pulse is not received at any station the station transmitter is automatically deactivated for a certain time becomes to a jumble of other impulses impede.

Of course, there are several reasons why a particular earth station may receive the sync pulse fails If the lack of reception of the Syncnronimpuises is due to an error at the receiving station, switching off the transmitting part of the receiving station in question is the most effective measure, to eliminate the problems that arise immediately. However, this possibility is quite unlikely since the majority of the satellite terminals are equipped with redundant assemblies in order to prevent such cases. Another reason for the lack of reception of a sync pulse can be that the sync pulse is already missing at the transmitting station. In this case, of course, none can of the stations of the entire system receive the sync pulse, whereby the entire SystPm automatically is interrupted. This is of course an undesirable situation in any case.

V- η starting from this last-mentioned failure phenomenon, proposes the US-PS 38 78 339 another alternative, namely that each station is to receive the Synchronized pulse monitored. If it is indicated that the sync pulse is not available, switch *, each Station for a predetermined period of time. In addition, every station receives from everyone other station an indication of whether the sync pulse has also been lost at these other stations. If a majority of the stations indicate a loss of sync pulse during the predetermined time period, a certain of the remaining stationers feeds a new sync pulse into the network system. The reason why it is required in this case that a plurality of stations coincide with the Report the loss of the sync pulse, makes sense, namely to exclude the possibility that the sync pulse loss indicator indicates a local malfunction is due, although the reference station has emitted the sync pulse. Will this If this possibility is not prevented, it can easily happen that two stations generate a synchro-pulse feed different cycle times into the network, which can easily give rise to confusion and an effective Excludes operation of the S> r, tems. So much for the stations geographically separated, and to ensure that each station has an indication

whether each of the other stations receives the sync pulse must be a display or signal channel are available for this purpose between the stations.

Although there is currently no reason to believe that this proposed system could not work or work incorrectly, it is obvious that the Efficiency and economy are limited by the fact that a special channel is required via which each station sends a message to every other station as to whether the sync pulse has been received will. In addition, an additional device is required to query the reception of the sync pulse and provide a corresponding signal indication, receive signal indication from other stations, and the inherently necessary logical operations to trigger the intended functions of the System. This system must also be able to continue during the reconstruction phase of the Duty cycle in the entire interconnected network can manage without a reference synchronous pulse during certain intervals, which are greater than the signal wave delay for a reciprocating signal flow across the satellite. This places considerable demands on the stability and absolute accuracy of the frequency standards of the individual satellite terminals.

The invention is based on the object of a method for synchronization and a synchronization device for TDM A communication networks, especially for satellite messaging too create, through which a perfect synchronization without extreme demands on the frequency constancy the individual satellite terminals can be reached even if the usually transmitted, Synchronization pulse supplied by a reference station incorrect for some reason is transmitted or fails.

This technical problem is solved according to the invention according to the measures specified in the claims.

A TDMA communication system that can be synchronized according to the invention has as essential characteristic features with a plurality of stations that communicate with each other via a common communication link are in contact, an assembly for the periodic emission of a primary sync pulse, another unit for the periodic emission of a secondary sync pulse, an interrogation circuit a pulse synchronizer at a majority of the stations to detect both sync pulses each of the plurality of stations for maintaining the transmission pulses within that station a predeterminable time slot and a device also provided in this plurality of stations on, which responds to the interrogation circuit and monitors the pulse synchronizer to ensure the synchronization to be maintained even if the primary sync pulse fails

The inventive method for maintaining the synchronization of a number of by time division multiplex with multiple access (TDMΑ system) connected to each other via a communication link Stations if a primary sync pulse fails, usually within a certain cycle time occurs in a short summary of the following process steps:

- A secondary synchronization pulse to be received by the stations is generated within each cycle duration radiated;

- each station is normally synchronized to the primary sync pulse while on absenteeism of the primary sync pulse the

- Synchronization of each station on the secondary Synchronization pulse takes place.

The invention thus provides for the transmission of a secondary sync pulse in addition to the reference sync pulse before. This secondary sync pulse is preferably emitted by another station than the one emitting the reference sync pulse. Both the reference sync pulse and the secondary sync pulse occur within the time frame specified by the system, i.e. within of a cycle period and both pulses are received by each station in the system. The secondary Synchronization pulse is primarily used for pre-setting one in the Syrichronisationssysie "; each terminal existing counter that is reset by the reference sync pulse. This through the secondary The counter set by the sync pulse and reset by the reference sync pulse is that of the Specifies and monitors the transmission time for the station. If the reference sync pulse is in the correct Receive clock and time ratio, the secondary sync pulse has no influence on the counter, because dL-ser following the presetting by the secondary sync pulse is reset by the reference sync pulse. On the other hand, is the reference sync pulse does not exist, the timing of the radiation of this station is controlled by the secondary Sync pulse causes. The synchronization can thus be maintained automatically without additional logical assemblies or an additional information channel must be available. The stations which is the specific sync pulse or the secondary sync pulse radiate are fixed. The station that emits the secondary sync pulse receives it Pulse on the reference sync pulse. If the reference sync pulse fails, then of course receives the station transmitting the secondary sync pulse does not receive the reference sync pulse either. In this In this case, the station emitting the secondary sync pulse becomes the reference station.

The invention is explained in more detail below in exemplary embodiments with reference to the drawing. It shows
F i g. 1 is an example of a typical time frame; F i g. 2 shows the block diagram of a station;

F i g. 3 shows the block diagram of an embodiment of a Generator for generating a specific time slot or a radiation opening or time aperture; F i g. 4 shows the block diagram of an input detector;

F i g. Figure 5 is a block diagram of an embodiment of a pulse synchronizer;

F i g. 6A and 6B show the block diagram of a preload generator;

7 shows the block diagram of another embodiment shape of a bias generator and

8 shows the block diagram of another embodiment form of a pulse synchronizer.

To facilitate understanding of the invention, a TDMA system will first be described for there the invention is well suited. 1 illustrates a typical time frame. The Term "time frame" the representation of a temporal!

Understand the sequence of transmission signals and the way in which the signals emitted by each of the stations are received at the satellite. F i g. 1 shows that the time frame comprises a pair of sync pulses, namely the sync pulse S and the sync pulse P and a plurality of data pulses; in the example of FIG. 1, this is 15 data pulses or data bursts. For example, the counting may comprise a period of 75 sec, which is shown in FIG. 1. The size or format of each data burst is identical, and FIG Includes sections labeled CR / BTR, UW, SIC, VOW, TTY, OW, BER, VFI, DDI and DSI The first part of the data burst includes a certain period of time for carrier recovery and bit timing recovery (CR / BTR = Carrier Recovery / Bit Timing Recovery); the relevant functions are known to the person skilled in the art. The next section of the burst consists of a password (UW = Unique word), which specifies the start of the burst. The letters SIC refer to the station identification code (SIC = Station Identification Code) that identifies the sending station. The remaining sections of the burst comprise different data channels of various types or formats, such as a voice channel, a telex channel, in the format individual adapted speech channels, a format for direct digital data transmission and other formats for multiple transmission of collectively coded speech channels.

The section of the burst assigned to the bit error rate enables the channel transmission to be checked by determining the frequency of job or bit subjects.

Each of the sync pulses is identical in terms of its format; Fig. 1 also illustrates one typical sync pulse. The first section of this ben. This ensures for the entire system that at least a single sync pulse is present at any time in the time frame. D; \ with can open the automatic replacement of the Bcr, ..sstation waived so that the complexity in the construction of the hardware is not insignificantly reduced. Furthermore the probability of an intervention in the overall network without a sync pulse on those is reduced Cases in which both sync pulses fail at the same time - very unlikely in practice and a rare case.

The block diagram of FIG. 2 illustrates the structure of a typical terrestrial terminal. The assemblies This station can basically be divided into common units and a plurality of connection or Subdivide connection module, hereinafter referred to as interface module. These interface modules are used for time division demultiplexing, PCM encoding / decoding and for sub-burst compression expansion functions, to be processed terrestrial signal forms (e.g. voice, data, supergroups, etc.) for the common TDMA facility to prepare. Each interface module is assigned to the common structural units as an individual assembly, A maximum degree of flexibility and good economy in the design of the entire TDMA system to ensure. The types of interface modules required can vary at the individual locations considerably different from those required at other stations. Because of this, differ the interface modules at two stations often vary considerably. There is also a coding used for forward error correction with the option of using the special error coding on both the data service as well as the relationship between the data service and utilization considerations for the uncoded terminal satellite terminal

SynCnrönirnpü'ses will be able to adjust connections together with the Datersbu.-st.

used for carrier recovery and bit clock recovery. The sync pulse also includes a password (which differs from the corresponding single word of the data burst) around the sync pulse to be identified as such. Finally, the sync pulse contains a station identification code to enable the identify the station emitting the sync pulse.

In accordance with the invention, particularly new to this time frame is the use of a sync pulse pair, namely a primary sync pulse P and a secondary sync pulse S. The way in which these sync pulses are sent, received and used in the TDMA system to maintain synchronization , is the subject of the invention. It is especially important that the sync pulses S and P are sent from different stations. The primary or reference station sends the P-pulse fP-Burst), while the secondary station emits the S-pulse fS-Burst) Ensure sorting of the respective data bursts. If this station does not receive a P pulse for any reason, the S pulse is still available to ensure the necessary reference. If some stations agree that the r-pulse has been lost, another station can be selected manually, for example, in order to now deliver the secondary sync pulse. a demultiplexer 30 connected. The multiplexer 16 provides each of the interface modules 10 to 15 with specific timing signals, so that each interface module can transmit its data to the multiplexer 16 in a specific assigned time. The data from each of the various interface modules are called "sub-bursts". These sub-bursts are sent to the common modules and are given the prefix there to form the entire data burst. The demultiplexer 30 does the reverse operation; That is, it receives the sub-burs on the input side and sends each sub-burst to the assigned interface module. Both the multiplexer 16 and the demultiplexer 30 can work together with a plurality of very different interface modules, ie the ones shown in FIG. Interface modules illustrated in FIG. 2 are only to be understood as an example. In order to ensure the greatest possible flexibility, the multiplexer 16 and the demultiplexer 30 can also work together with different groups of interface modules that differ from those in FIG. 2 differentiate.

A burst synchronizer 25 monitors the timing of each station transmitter by issuing one Synchronization signal to the multiplexer 16. The latter is used to synchronize the preamble generator and to ensure that the data originating from each of the connected interface modules get to a scrambler 17 at the right time.

If the bias generator 18 is activated by a signal from the multiplexer 10, it begins to generate the? Opening credits for the respective timeframe. In the case of the "in FIG. In the overall time frame, the header comprises six sections of the data burst, ie the parts CR-BTR, UW, SIC, VOW, TTY, OW and BER. The preamble generator 18 generates a plurality of activation signals which are sent to an OR gate 19 in order to trigger the individual components of the preamble in order to have them available at the modulator 20. At the end of the leader, the multiplexer 16 enables the first data sub-burst to the scrambler 17. At the end of this sub-burst, another sub-burst reaches the scrambler 17, etc. The scrambler 17 serves to reduce the energy flux density which is transmitted when the information contains fixed data patterns. The structure of the scrambler 17 and the descrambler 29 are known, so that a detailed description can be omitted. A typical way of operating the scrambler 17. When to use modulo-2 addition with regard to the digital data stream with a pseudo-random sequence. The location or the assignment of a particular station data burst within the time frame is monitored in this way by the burst synchronizer 25, which ensures that the synchronizing signal activates the multiplexer 16 in order to start the transmission of data bursts. The burst synchronizer 25 receives its information from a unit 24 for determining or recording a specific time slot, which unit operates in a known manner during the initial recording or recording phase. An example of this is described in US Pat. No. 3,813,496. The burst synchronizer 25 also receives clock time information via the demodulator 28 and the bias detector 26 from the receiver at each station. The preload detector 26 is in particular able to receive both the primary and the secondary sync pulse as well as the own data burst assigned to the respective stations. Each of these bursts contains a specific individual word or password, and the preload detector 26 responds to the password contained in the P and S sync pulses as well as νλ the password of the local station data burst. This provides the synchronizer 25 with a reference to the timing of its own data bursts as well as information relating to the arrangement of the data burst with regard to the correct position. This latter information is used for fine monitoring of the position of the data burst in the time frame. An example of a device that fulfills this function is described in US Pat. No. 3,562,432.

In order to further explain the structure and mode of operation of the synchronizing device according to the invention, Let us first consider the bias detector 26, the bias generator 18 and the burst synchronizer 25 explained

However, before the structure of these assemblies is discussed in more detail, it appears for a better understanding attached to the invention to explain how the secondary and primary reference sync pulse to Ensuring synchronization can be used in each terminal. Assume that each station Is equipped with a facility to enable either the primary or the secondary Radiate sync pulse and also assume that two different stations of the system have been selected for these functions. The in F i g. The time frame shown in FIG. 1 thus includes both

IU

Synchronous pulses, namely the synchronous pulse S and the synchronous pulse P. It is also assumed that each station is equipped with a device to detect these two synchronous pulses and to deliver a signal that appears in the correct time sequence. which is caused by the secondary sync pulse is referred to below as Sync S and the other signal occurring due to the primary reference sync pulse as Sync P. As FIG. 3 shows, these two signals reach a binary counter 35 operated by a local clock pulse generator. Each station contains such a local clock pulse generator, the operating frequency of which is nominally identical within a certain tolerance limit. The purpose of the synchronization system is to compensate for the relative deviation of the individual clock pulse generators. The output signals of the binary counter 35 reach a comparator 36. The other input of the comp arators 36 is acted upon by a memory 37 with random access. This memory can be loaded manually from an I / O register 49, for example. The memory with random or random access is used to determine all significant circumstances within the time frame with regard to an expected count value of the binary counter 35. The memory 37 is addressed by a counter 38. The reset input of this counter is acted upon by the Sync P signal, while the output signal of the comparator, which is designated AfA TCH, is present at the clock input of this counter. Essential assemblies of the arrangement according to FIG. 3 is assigned a unit called an "aperture generator" which supplies a signal for each of the different data bursts as well as for the primary sync pulse. Each of the individual processes occurs in a specific time segment, which corresponds to a specific count value of the count value 35. If, in the present case, it is assumed, for example, that the primary synchronizing pulse should occur at the count value zero, then each of the other processes within the time frame can be determined from this reference value. Since in the typical time frame format in FIG. If the secondary synchronous pulse occurs a short time before the primary or reference synchronous pulse, the secondary synchronous pulse obviously appears some time before the counter 35 reaches the count value zero. Due to the small frequency differences between the clock pulse generators in the individual stations, a certain drift can be assumed in the unsynchronized operation of the counter. If the sync 5 signal is received in a specific station, it reaches the preset input of the binary counter 35, which is thereby set to a specific expected count value with regard to the occurrence of this signal. The primary or reference sync pulse resets the counter to a count of zero. It is clear to a person skilled in the art that in principle every count value in the counter can be used as a reference value, so that the value zero is only to be understood as an example

In normal operation, ie when the signals Sync S and Sync P are received, the counter 35 in each station is synchronized with the counter in that station which emits the primary reference pulse is synchronized, the secondary synchronic pulse always retains a predetermined relation to the primary

E.g. 4 /

3ynchror, impulse at. However, during normal operation, d. H. if both sync pulses are received, this is not an essential requirement for an effective one In fact, the reception of the secondary sync pulse is irrelevant if the primary Reference pulse is present and received. The reception of the primary sync pulse causes i.e. the synchronization of the binary counter for proper operation.

The output signal of the comparator 36, ie the MATCH signal, sets a flip-flop 39. The (^ output of this flip-flop 39 is connected to one input of an AND element 40, the other input of which is acted upon by the local clock pulse generator of AND gate 40 feeds a divide-by-seven circuit 41 which resets flip-flop 39 when an output signal occurs The (^ output of the flip-flops 39 is connected as an input to an AND element 42, at the other input of which the signal SyncP is present. The output of the AND element 42 is connected to the reset input of flip-flops 43 and 44 via a buffer amplifier 34. The set input of flip-flop 43 is connected to one input of an AND element 45, the other input of which g is acted upon by the (P output signal of the flip-flop 39. The output signal of the AND element 45 reaches the flip-flop 44 as a set input signal, the (^ output of which is connected to one input of an AND element 46, the other input of which is connected to the output signal of the divide-by-seven circuit 41 Finally, the output of the AND element 46 is connected via a buffer amplifier 47 to the reset inputs of the flip-flops 43 and 44. The output signal of the AND element 42 is the P signal and the output signal of the AND element. The dummy or auxiliary P signal is element 46. Each of these signals is applied to an input of an OR element 48, at the output of which the P signal or primary synchronizing signal for the burst synchronizer occurs.

FIG. 3 illustrates the diaphragm generator which monitors the two sections of the common piece of equipment of each terminal. The shutter generator supplies signals called aperture or shutter signals which increase the probability of the password or reference word detection and help to identify the beginning of each burst in order to ensure the correct decryption of the bursts received by the station concerned. In addition to this function, the diaphragm generator also supplies a synchronization signal to the burst synchronizer. This burst synchronizer actually only needs the synchronization signal periodically, usually only once every third of a second. The counter 35 directly monitors the generation of the individual aperture or opening signals for the reception time control. This counter is of course synchronized by both the Sync S and the Sync P signals to ensure. The operation of the counter is independent of which of these signals actually synchronizes it. However, the second function of the diaphragm generator, which supplies the burst synchronizer with the Sync P signal, depends on it. whether the Sync P signal is actually received. The counter and the device assigned to it naturally generate an opening or aperture for this signal, regardless of whether the Sync P signal is actually received or not. However, if this signal is not received, it obviously cannot be transmitted to the burst synchronizer either. There are now a number of options for synchronization

ίο can be maintained in the absence of the Sync P signal. In one of these possibilities, which is illustrated in FIG. 3, an auxiliary P signal is generated if the sync P signal has not yet been received by the end of the relevant time slot. This Hi'fs-P-signal then reaches the burst synchronizer as if it were the actual Sync P-signal itself. According to another embodiment of the invention, if a loss of the Sync P signal is detected, the diaphragm generator transmits the Sync 5 signal to the Bui'si-Syi'iC'Mi'üniSicrcr instead of the SjTiC P-signal. In this embodiment, some modifications are required to the burst synchronizer for the following reason: The burst synchronizer only works if the required delay between the received synchronization signal and the station's own data burst transmission is known in advance. The station's own data burst transmission is determined by querying the reference or password of this station, which is sometimes also referred to as the local password. The burst synchronizer is responsive to the delay between these two signals. To maintain correct synchronization when the Sync S signal is passed on to the burst synchronizer instead of the Sync P signal, the delay must obviously also be changed in order to compensate for the time differences between the occurrence of the Sync S and Sync P signals. This second embodiment of the invention is described with reference to FIGS. 7 and 8 described below. Initially, however, """will be used in the further explanation of the first embodiment of the invention with reference to FIG. 3 in conjunction with FIGS. 2 and 4 fc-: s 6 continued. In this embodiment, due to the logic used, the occurrence of the second sync pulse is not evaluated as an event, the count value of which is stored in the memory 37 with random access. As a result, the comparator 36 does not generate a MA7C7 / signal, so that no time slot is generated for the secondary sync pulse either.

As mentioned, the memory 37 with random access stores the expected count value of the counter 35 and thus defines the significant events within the time frame, e.g. B. the occurrence of the Sync P signal and the occurrence of each data burst password signal.

Since the clock pulse generators at the individual stations can be shifted in terms of frequency from one another, an opening is created within which the expected signal can be received. The start of the time opening may actually be before the nominal or expected time of a particular event. For example, the optional memory can hold a count that is slightly before the expected count of the counter 35 when the Sync P signal is received.If this count is reached, a MATCH output appears on the comparator 36. This signal sets the flip-flop 39 , the output of which activates the AND gate 40 so that the clock pulses can reach the divider 41. The flip-flop

39 therefore ensures that a Zeitöffaung during the seven-symbol runtime of the divider 41. This activates the gate 42 so that the sync P- pulse can happen when this occurs, so that the P-signal is generated. The P-pulse reaches the burst synchronizer via the OR gate 48 for synchronization. The P signal also resets flip-flops 43 and 44.

If the sync P pulse is not received for any reason, the following operations take place: The sync S signal sem apart from the presetting for the counter 35 (which is synchronized with it) the flip-flop 43. The time is opened by the counter 35 is triggered when the count value is reached at which the Sync P signal is expected and the flip-flop 3S is set, the AND element 45 (which is activated by the setting condition of the flip-flop 43) sets the flip-flop 44 The output signal of the flip-flop 44 arrives at an input of the AND gate 46 which, when the parts-sifting circuit 41 sends an Ausgarigssigna! supplies, is activated so that an auxiliary f-pulse can oassieren. This has the effect of resetting both flip-flops 43 and 44 via the buffer amplifier 47 and also the switching through of a P signal to the burst synchronizer for synchronization purposes via the OR gate 48. Even if there is no primary synchronization pulse, a synchronization signal is available for the burst synchronizer that is not shifted by more than ± 3 symbol times compared to the theoretically correct reception time. More important than the generation of the auxiliary reference signal, however, is the fact that the device which generates the auxiliary reference signal is synchronized by the action of the secondary synchronizing pulse which controls the status or operating state of the binary counter 35.

To explain how the signals Sync S and Sync P are generated by the bias detector, refer to the block diagram of FIG. 4 referred to. A look at the figure shows that the front tension detector 26 receives the demodulated signal received from the satellite. Since this is a four-phase PSK signal, there are two pulse trains or pulse trains, P and Q , which are sent to a twenty-bit shift register 50. The shift register 50 is connected to the multiplexer 51 to receive signals which indicate to a password detector 52 a synchronization password or a data password. A password has a special pulse pattern, and the person skilled in the art is familiar with the structure of such password detectors; an example of this is described in US Pat. No. 3,796,868. The password detector 52 provides signals indicative of either a data password or a sync signal password. The synchronous signal password, which is generated when a synchronous password occurs, reaches the SIC detector 53 (station identification code detector) and a pair of AND gates 54 and 55. The SIC detector 53 decrypts the individual SIC codes and thereby identifies them either the reference station or the station emitting the secondary sync pulse. The Q input is connected to the SIC detector 53 and thus recognizes the SIC code for each of the stations. This SIC detector 53 thus delivers SIC-P or S1C-5 output signals depending on the received station identification code of the station emitting the primary or secondary sync pulse. These signals go to AND gates 54 and 55. When a synchronous password signal and a SIC-P signal occur at the same time, the AND gate 54 delivers the sync P signal Presence of the sync password signal and the SIC-S signal. These signals then reach the counter 35 as inputs (see FIG. 3).

Before explaining the bias generator, the not just the preamble for each station data password, but also the synchronization pulse

ίο delivers if this station is either the primary or secondary synchronization station, let us first consider the burst synchronizer and the way in which it does this Output signal of the diaphragm generator (Fig. 3) is used, to maintain synchronization.

This explanation can be kept brief since burst synchronizers of the type described here are known per se and are described, for example, in the aforementioned US Pat. No. 3,562,432.
FIG. 5 illustrates the burst synchronizer: an oscillator 60 generates clock signals for a reference time frame counter 61. This time frame counter counts the number of symbols N contained in a time frame. However, the counter 61 can be controlled by the reset control 63 to divide by either (N + 1) and / or (N- 1) for reasons explained below. Each decade of the time frame counter is fully decimally decoded by decoder 62. By using AND gates with multiple inputs, time stamps are generated for each symbol time during the time frame for the tens

is decade and a decoded 8 for the ones decade correspond, a pulse with a width of one symbol will appear at the output of this AND element and this symbol corresponds to the symbol 5218 in the time frame. Around a window or a gate two such time stamps control the set and reset inputs of a flip-flop. With With this technology, all essential timing impulses, gates and functions required by the transmitter can be used of the TDMA system. The burst synchro

The controller also supplies monitoring signals to the multiplexer (see Fig. 2), reproduced by the synchronous input of the multiplexer 16.

To maintain normal steady burst synchronization, the desired position is one

so bursts are of course known and are previously entered in a delay counter 64 entered. At certain intervals, about a third of a second, the P signal becomes (made available by the Biendengeneratot of FIG. 3) and selected by a correction logic 65 is keyed to begin counting down the delay counter 64. When the delay counter reaches If the count value is zero, a pulse called a delayed P-pulse appears. Within de! In the same time frame, the determined local password, i. H. through the station in which the hiei described facility is, emitted password selected and timed by the Komparato 66 with the arrival of the delayed P-pulse ver resembled. The two impulses arrive at the same time. s <the local burst is in the correct time frame position tion. If the two pulses arrive at different times, the amplitude and polarity of the sub measured and is stored in symbol units

In particular, an AND element 67 is gated on when one of the two pulses arrives at the comparator 66 and blocked again when the second pulse arrives. During this activation time of the AND element 67, an up / down counter 68 counts the number of local symbol clock pulses that were generated within this interval. The local burst is then shifted to the correct position in the time frame by forcing the time frame counter to divide by (N + 1) or (N- 1) during a number of symbols which is the phase difference between the delayed A signal and the local burst for each Time frame in which the time frame counter divides by an amount other than TV, the AND element 69 reduces an up / down counter error memory 68 by a single counting step. Whether the time frame counter divides with (N- \) or (N +]) is determined by an error polarity detector 70 which is scanned either by an AND element 71 or an AND element 72, depending on whether the "-Signa!" or a local password signal arrives at the phase comparator 66 first.

The ratio between the A signal and the local password signal is measured every third of a second, which is determined by the total delay of the m satellite

The Fig.6 shows the bias generator that the Each station's header for the station data burst and also for the synchronization burst for either the reference sync signal or for the secondary syn- 3 <i chronsignal of the sending station determined

The header start command from the multiplexer 16 activates a decoding counter which generates the various key signal functions required for the data combination during the carrier replay. recovery and the bit clock recovery section of the header activates a gate (CR / BTR gate) a sequence of ones for the P and Q Kzna \. A four-bit counter that is reset by the preamble start signal is activated. The password and the station identification code sequences are generated by tapping the desired decoded outputs using changeable, optionally usable bridges. Two different passwords are created using two sets of tapping 4; gen or taps, one being the data burst password and the other being the reference burst password, which is only triggered if the station in question is determined to be one of the reference stations 5C

In particular, the flip-flop 101 present in the secondary reference station is only set in the station which is intended as the sending station for the secondary sync pulse. Correspondingly, a flip-flop 102 which is decisive for the primary reference station is only set in that station which is selected for the transmission of the primary sync pulse. The outputs of these flip-flops reach the inputs of AND gates 103 and 104. The other inputs of AND gate 103 are acted upon by the decoded output signals μ of time frame counter 61 (see FIG. 5), which identify the time during which the secondary sync pulse is to be transmitted. The other inputs of the AND element 104 are correspondingly connected to the outputs of the decoder 62 of the burst synchronizer (see FIG. 5), which defines the time during which the primary sync pulse is to be transmitted. The outputs of the AND gates 103 and 104 act on an OR gate 105, the output signal of which in turn goes to an AND gate 106 and an inverter 107. If the output signal is present, the AND gate 106 is activated and gives the password gate free for the 4-bit counter mentioned above. At the same time, the output signal of the inverter 107 inhibits an AND element 108, which consequently cancels the passage of the password gate. The output signal of the AND element 106 is thus available to enable the transmission of either the primary or the secondary sync pulse. The output signal of the AND element 108 is accordingly present in order to enable the transmission of the password assigned to the station data burst.

The previous description explains how both a primary and a secondary sync pulse can be transmitted from a specific station. Of course, in practice only one of these pulses would be emitted from a station and there would only be two stations in the entire system It was also explained how the preload detector detects the presence of either the primary or the secondary sync pulse and makes this signal available for the band generator of the secondary and primary sync pulses are synchronized within the time frame and how the shutter generator monitors the pulse synchronizer to control the transmission timing of a particular station pulses ensures synchronization of the stations even if the primary sync pulse is not received. This flexibility ensures that the TDMA synchronization still works correctly if the station emitting the primary sync pulse is faulty and, for example, the primary sync pulse fails completely. In this case, the station emitting the secondary sync pulse automatically becomes the synchronization station for the overall system. If the absence of the primary sync pulse is confirmed, which can be done, for example, by manual transmission, a second static can be selected to send another sync pulse that activates a specific flip-flop, such as flip-flops 101 or 102 in F i G. 6th

It has already been mentioned that in another embodiment of a device according to the invention the auxiliary P signal is not generated and instead the Sync 5 signal is transmitted to the pulse synchronizer for the purpose of synchronization. As already mentioned, the delay counted by the pulse synchronizer must be changed if the Sync S signal is used instead of the Sync P signal in order to compensate for the time difference in the occurrence of these two signals. In this embodiment, the Sync S signal is regarded as an event the occurrence of which is stored in random access memory. As a result, the comparator 36 generates the MATCH output signal at the expected time of receipt of the Sync S signal or when the counter 35 reaches the count value at which the Sync S signal is expected.

In this embodiment, the diaphragm generator has that illustrated in FIG. 7, for example Structure on instead of the circuit structure according to FIG. 3. It is evident that the greater part of the arrangement

18th

7 shows a correspondence in the circuit according to FIG 3 also has the presence of the gates 86 and 87. In this embodiment, the pulse synchronizer (Fig.5) also illustrated in Fig.8 Build on; in this case too, the majority of the assemblies in FIG. 8 an equivalent in the circuit according to FIG. 5.

In the case of the diaphragm generator to be described first, it is noticeable that the logic required to generate the auxiliary P-signal has been omitted. The memory with direct access now stores the count value assigned to the received Sync 5 signal, ie the comparator generates the MA 7CT / signal this event. The signals Sync P and Sync S apply to an input of a pair of AND gates 86 and 87, at the other input of which the aperture signal generated at the (? Output of the flip-flop 39 occurs S or P signals to be superior In normal operation, ie when both the SyncP and the Sync S signals are received, the gates 86 and 87 supply the P and S signals, respectively Fig. 8 (which is not included in Fig. 5) comprises a modified delay counter 88 and a gate 85. The modified delay counter 88 is acted upon by the signal supplied by the loss of synchronization logic 73. This unit merely detects the absence of the P signal ; It can also be designed so that it responds to the absence of a single primary Syro hronimpulses Since on the other hand, the error correction component determining logic a P signal for transmission to the Impulssyn chronisierer selects after about V ₃ SexiKide in such a way that a correction is not required more than once per second, the logic which detects a loss of synchronization can add up to the loss of three primary sync pulses before it becomes effective. Represents the loss of synchronization logic, the absence of the required number of primary synchronization pulses firmly so it emits a signal to the * o modified delay counter 88 and an input signal to the AND gate 85th The delay counter 88 merely adds to the delay value of the delay counter 64 that is present between the primary and secondary sync pulse. At the same time, when the S synchronization signal is generated, the AND element 85 forwards this signal to the delay counter via the logic for error correction. The pulse synchronizer has thus synchronized the station to the secondary sync pulse. The inverter 89 and the AND gate 90 work together in such a way that the P signal is prevented from reaching the logic for error correction when the primary sync pulse reappears

In the case of the FIG. 7 and 8 modified embodiments is therefore instead of generating a Auxiliary P-signal the 5-signal for maintenance the synchronization of the station is used by the pulse synchronizer. Receives the secondary Station that emits sync pulse in turn sends the primary sync pulse, so it works Station as a relay to maintain the synchronization of the entire system. Receives the Secondary sync pulse emitting station, however, does not receive the primary sync pulse, so it will even to the destination station in terms of synchronization. The pulse synchronizer at this station is determined by the scan logic for loss of sync shut down, which cooperates with the facility, which determines the transmission of the secondary sync pulse

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55 Here are 8 sheets of drawings

Claims (16)

Patent claims: 1. Procedure for maintaining synchronization a number of time division multiple access (TDMA system) over a communication link Interconnected stations be: failure of a primary synchronization pulse, which is usually within a timeframe cycle duration occurs, characterized by the following process steps: a) Sending out a to be received by the stations secondary sync pulse within each time frame; > 5 b) Synchronization of each station to the primary synchronization pulse and c) Synchronization of each station to the secondary synchronization pulse when absent of the primary synchronization pulse set 2. The method according to claim 1, characterized in that the process section b) in the following Process steps is divided into: (i) Operating a counter with a pulse train nominally for a number of stations is equal to; (ii) Catching and, if necessary, selecting the primary Synchronization pulse; (iii) Reset the counter using the primary Synchronization pulse and (iv) Monitoring of the station based on the operating status or status? Counter. 3. The method according to claim 1 or 2, characterized in that the process section c) the following Process steps include: 40 (i) Interception and, if necessary, selection of the secondary synchronization pulse; (ii) Presetting the counter by means of the secondary synchronization pulse and (iii) Monitoring the station based on the momentary Meter reading. 4. The method according to claim 1 or 2, characterized characterized in that process section c) comprises the following process steps: (i) query of the presence or absence of the primary synchronization pulse; (ii) generating an auxiliary synchronization signal and (iii) Synchronization of the station to the Hilt's synchronization signal. 5. The method according to claim 1 or 2, characterized in that the process section c) the following Process steps include: (i) query of the presence or absence of the primary synchronization pulse; (ii) Processing and transmission of the secondary synchronization pulse to a synchronization unit and (iii) Setting the synchronization unit to the correct one Synchronization with regard to the secondary synchronization pulse. 6. Synchronization device for TDMA communication networks with a plurality of through Time division multiplexing with multiple access via a communication link between connected stations for maintenance synchronization even in the event of failure and / or malfunction of the by a reference station transmitted synchronization pulse, characterized by a device for periodic Delivery of a primary synchronization pulse; a device for the periodic delivery of a secondary Synchronization pulse; an interrogation device provided in several of the stations for the synchronization pulses; a pulse synchronizer in each station to ensure that the Transmission pulses from this station are kept within a specified time slot, and by a monitoring circuit that responds to the interrogation device in the relevant stations for the pulse synchronizer to maintain the current state synchronization even if there is no primary synchronization pulse. 7. Device according to claim 6, characterized in that the monitoring circuit has a counting device controlled by clock pulses, the so '<ohl on the primary, as well as on the secondary synchronization pulses responds. 8. Device according to claim 7, characterized in that the counting device by the secondary Synchronization pulse can be set and reset by the primary synchronization pulse is. 9. Device according to one of the preceding claims 6 to 8, characterized in that the Period durations of the primary and secondary synchronization pulse are equal to one another. 10. Device according to claim 7 or 8, characterized by a memory, the one at the time of the primary synchronization pulse determines the expected count value of the counting device, a comparator connected between the memory and the counting device, which supplies a signal, as soon as the count value accumulating in the counting device reaches the value held in the memory hit, as well as one on the output of the comparator and logical combination circuit responsive to the presence of the primary synchronization pulse, which emits a synchronization signal that acts on the pulse synchronizer. 11. Device according to claim 10, characterized in that that the logic circuit in the absence of a primary synchronization pulse an auxiliary synchronization signal is generated. 12. Device according to claim 10 or 11, characterized by a module responding to the comparator for generating a time fade, while the primary synchronization pulse is to be expected. 13. Device according to one of the preceding claims 10 to 12, characterized in that the logic circuit unites by the generation the timer can be activated for a short time includes, over which the possibly arriving primary Synchronisaiionsimpuls on the impulse synchronizer got. 14. Device according to one of the preceding Proverbs 10 to 13, characterized in that the Logic circuit one on the secondary synchronization pulse and when the primary is absent Synchronization pulse to the end of the time aperture responsive bistable trigger circuit for Generation and delivery of the auxiliary synchronization pulse to the pulse synchronizer 15. Device according to claim 11, characterized in that that the pulse synchronizer includes delay counting circuitry and loss of sync interrogation logic has a setting circuit for the delayed counting circuit feeds and the response of the pulse synchronizer activated on the secondary synchronization pulse 16. Device according to claim 15, characterized that the setting circuit programs the delayed counting circuit to a count value, which corresponds to the delay between the secondary and the primary synchronization pulse